System and method for detecting leaks

ABSTRACT

A leak detection system includes a pressure system that requires leak and/or pressure testing. A pressure sensor coupled to the pressure system senses a first pressure at time 0 , after which fluid pumping system provides a selected volume of test fluid to the pressure system. The pressure sensor senses a test pressure at time 1  and at selected intervals ‘n’ to time (n+1)  and transmits a signal reflect of the pressures at each time to a general purpose computer for recording and storage on a computer readable medium. An operating program is configured to calculate a leak detection value, which is a function of a ratio of the first pressure at time 0  and the test pressure at time 1 ; the test pressure at time 1  and the test pressure at time 2 ; and so on to a test pressure at the time and the test pressure at the time (n−1) . A graphical output is configured to display the leak detection value as a function of time.

PRIORITY CLAIM

This application claims the benefit of and priority from U.S. Provisional Patent Application No. 61/234,736 filed Aug. 18, 2009 and entitled System and Method for Detecting Leaks and U.S. Provisional Patent Application No. 61/311,863 filed Mar. 9, 2010 and entitled System and Method for Detecting Leaks, each being incorporated in its entirety for all purposes by this reference.

FIELD

Embodiments of the present invention relate to systems and methods for detecting leaks and for testing the pressure integrity of a pressure system, examples of which includes various systems configured to hold and or transport fluids, such as liquids and gases. Non-limiting examples of such pressure systems include pipelines, storage containers, hydraulic/fluid lines, valves, seals, and other similar systems designed to retain a fluid, whether a gas, a liquid, or combination thereof.

BACKGROUND

Tubes, valves, seals, containers, tanks, receivers, pressure vessels, pipelines, conduits, heat exchangers, and other similar components, are typically configured to retain and/or transport fluids under pressure. For purposes of this application, these different components are referred to as a pressure system and comprise one or more of the above components and their equivalents and, optionally, include other components. A non-limiting example of a pressure system includes a pipeline for transporting natural gas or other hydrocarbons. Another non-limiting example is a natural gas and/or oil well and/or wells of other types, whether being actively drilled or already producing, that typically transports fluids from the producing geological formation to a well head. Such a well includes one or more of the following components: a Christmas tree or well head; production tubing; casing; drill pipe; blowout preventers; completion equipment; coiled tubing; snubbing equipment; and other similar and typical components. Yet another non-limiting example includes hydraulic and fuel lines of various types for transporting fluids for use in mechanical devices. Yet another non-limiting example includes storage containers for retaining fluids therein. Other pressure systems fall within the scope of the disclosure.

The fluids retained or transported within pressure systems typically include one or more gases, liquids, or combinations thereof, including any solid components entrained within the fluid. As one non-limiting example, a typical fluid comprises methane or natural gas, carbon dioxide, hydrogen sulfide, natural gas liquids, water, and the like. Another non-limiting example is crude oil, which typically includes methane, propane, octane, and longer-chained hydrocarbons, including heavy oil/asphaltenes. Yet another non-limiting example is hydraulic fluid within a hydraulic line.

Pressure systems and/or the individual components that comprise the system, typically are tested to ensure that the pressure system is not leaking and/or the pressure system is capable of maintaining pressure integrity. For example, a pressure system typically is tested to provide assurance that the fluid system is capable of retaining the fluid held therein at a selected pressure (e.g., a maximum pressure rating or maximum rated pressure) without the fluid leaking or escaping from the pressure system.

It is understood that in connection with fluids and gases that exhibit a potentially significant change in pressure as a function of the fluid's temperature, it can be difficult to determine whether a change in pressure, typically, although not necessarily, a decrease in pressure, in a pressure system is merely a result of the change in temperature of the fluid, or if it is a result of a leak somewhere within the pressure system. For example, a fixed volume of a synthetic drilling fluid in a suitable container/pressure vessel used in oil and gas drilling exhibits a decreasing pressure as a function of temperature. Depending on the drilling fluid involved, the pressure can very significantly with temperature. In deep water offshore drilling in which the drilling fluid at a temperature of between 80° F. to [20° F. at the surface, the temperature fluctuation can be quite large. For example, the fluid cools as it passes from the drilling platform, through drill pipe and/or the riser that is surrounded by the ocean, to a wellhead or blow-out preventer that can be several thousand feet below the surface of the ocean and on the sea floor where the ambient, surrounding water temperature might be as low as 34° F. Thus, there is a large and rapid transfer of heat energy from the drilling fluid, through the containing drill pipe and/or riser, to the surrounding ocean, which, in turn, causes a sometimes significant decrease in the pressure of the fluid held within the pressure system. A problem is to distinguish this drop in pressure caused by the decrease in temperature from a drop in pressure caused by a leak within the pressure system that is allowing the fluid held therein to escape.

To solve this problem of distinguishing the cause of the drop in pressure, operators of pressure systems often frequently hold a test pressure within the pressure system for a significant period of time, ranging from [0 minutes to well over an hour, until a steady-state test pressure (i.e., one in which the test pressure changes very little with time) is reached. That is, it may be only after a steady-state pressure is reached that an operator might be assured that a decrease in pressure was a result of the fluid cooling via a transfer of heat from the fluid to the sea and/or other surrounding media rather than because of a leak.

In addition, tests may be repeated several times to rule out various factors that affect the test results, such as how steadily the test fluid is added, mistakes in the test procedure, additional confirmation for assurance, and the like. The result is that significant and, often unnecessary, time is spent performing the leak/pressure tests. This is very expensive because the tests could take from 12 to 24 hours to complete when, for example, an offshore drilling vessel or rig that leases for $800,000 per day. Thus, significant savings in time and money can be made if a more efficient and accurate system and method of detecting leaks is found.

Other methods, including those that require complex calculus, differential equations that calculate an equation to fit observed data, and the like, have been proposed to reduce the time it takes to conduct a leak/pressure test. These older tests, however, typically rely on models that require accurate entry of various details of the pressure system, meticulous test protocols that must be adhered to strictly; and highly trained personal. In turn such systems can be impractical in many applications.

Thus, there exists a need for a system that can accurately perform a leak/pressure test, particularly for fluids including gases that demonstrate a change in pressure with a change in temperature that is simple, and does not require complex models or sufficient data to solve differential equations.

SUMMARY

It is to be understood that the present invention includes a variety of different versions or embodiments, and this Summary is not meant to be limiting or all-inclusive. This Summary provides some general descriptions of some of the embodiments, but may also include some more specific descriptions of other embodiments.

Embodiments of a leak detection system include a pressure system configured to hold a first volume of a fluid at a first pressure at an initial time, time₀. Optionally, the first volume is zero, i.e., the pressure system holds no fluid (other than ambient air, for example) at time₀ and, therefore, the first pressure is ambient or atmospheric and deemed to be approximately zero. A fluid pumping unit is coupled to the pressure system, non-limiting examples of which include cementing units, pumps of various types (e.g., centrifugal, duplex, triplex, positive displacement and eductors) all powered by appropriate means (e.g., hydraulic, electric, or any other suitable source of energy to cause a pump to operate), and other devices, such as a syringe or pipette to supply fluid to a pressure system of very small volume that may be found in laboratory equipment, and the like. The fluid pumping unit is configured to supply a selected volume of a test fluid to the pressure system. The volume of test fluid depends, in part, on the size of the pressure system, and can be from small amounts, such as microliters for laboratory equipment, to large amounts, such as barrels and more, for large pressure systems, as might be expected with pipelines and oil wells. Adding the test fluid to the pressure system raises the pressure at which the fluid within the pressure system is confined, such that a test pressure (i.e., the pressure within the pressure system after the test fluid is added to the pressure system) at time1 is greater than the first pressure at time₀. The test pressure exhibits a change in pressure, such as a decrease in pressure, with time as a temperature of the fluid (both the test fluid and the first fluid) decreases with time. In other words, the test pressure decreases over a time interval time₀ to a time1 regardless of whether any leaks are present within the pressure system.

Embodiments of the leak detection system also include a general purpose computer configured to accept and store an operating program and data as a function of time on a computer readable medium, such as a hard drive, flash memory, compact discs, data tapes, and the like. At least one pressure sensor is coupled to the pressure system and the general purpose computer. The pressure sensor is configured to sense the first pressure and the test pressure at time to, time1, at time₂, to a time_((n−1)), and transmit a signal reflective of the first pressure and the test pressures at each of the times to the computer to be stored on the computer readable medium.

Embodiments of the operating program are configured to calculate a leak detection value, which is a function of a variance of a percentage change in pressure over time, such as the percentage change in a difference in the first pressure at time₀ and the test pressure at time1; the test pressure at time1 and the test pressure at time₂; and so on, for a given plurality of intervals of time On′ to a test pressure at the time and the test pressure at the time_((n+1)). A benefit of this method is its relative simplicity and accuracy and that it does not require complex formulas or equipment to use.

Embodiments of the system also include a graphical output coupled to the general purpose computer. The graphical output is configured to display the leak detection value as a function of time. Examples of the graphical output include monitors, printouts generated by a printer, web pages that have had the leak detection value transmitted to them via a server or other internet connected coupled to the general purpose computer, dedicated displays and/or dumb terminals, and the like.

Methods of using the above described system to detect leaks are also disclosed.

As used herein, “at least one,” “one or more,” and “and/or” are open-ended expressions that are both conjunctive and disjunctive in operation. For example, each of the expressions “at least one of A, Band C,” “at least one of A, B, or C,” “one or more of A, B, and C,” “one or more of A, B, or C” and “A, B, and/or C” means A alone, B alone, C alone, A and B together, A and C together, B and C together, or A, Band C together.

Various embodiments of the present inventions are set forth in the attached figures and in the Detailed Description as provided herein and as embodied by the claims. It should be understood, however, that this Summary does not contain all of the aspects and embodiments of the one or more present inventions, is not meant to be limiting or restrictive in any manner, and that the invention(s) as disclosed herein is/are and will be understood by those of ordinary skill in the art to encompass obvious improvements and modifications thereto.

Additional advantages of the present invention will become readily apparent from the following discussion, particularly when taken together with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

To further clarify the above and other advantages and features of the one or more present inventions, reference to specific embodiments thereof are illustrated in the appended drawings. The drawings depict only typical embodiments and are therefore not to be considered limiting. One or more embodiments will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:

FIG. 1 is a block diagram of an embodiment of the leak detection system;

FIG. 2 is an example of an embodiment of the leak detection system used to test a blowout preventer on an oil rig;

FIG. 3 is an example of a plot of actual raw data created by an embodiment of the invention;

FIG. 4 is an example of a plot of a series of leak detection values calculated from the raw data plotted in FIG. 3;

FIG. 5 is an example of a plot of actual raw data created by an embodiment of the invention;

FIG. 6 is an example of a plot of a series of leak detection values calculated from the raw data plotted in FIG. 5;

FIG. 7 is a flow chart of an embodiment of the method of detecting leaks;

FIG. 8 is a continuation of the flow chart in FIG. 7 of an embodiment of the method of detecting leaks; and,

FIG. 9 is the example of a plot of actual raw data in FIG. 3 with different and additional aspects noted as they relate to another embodiment of the invention.

The drawings are not necessarily to scale.

DETAILED DESCRIPTION

A block diagram of an embodiment of the leak detection system I of the present invention is illustrated in FIG. 1. The leak detection system I includes a pressure system 5. Tubes, valves, seals, containers, vessels, heat exchangers, pumps, pipelines, conduits, and other similar components, are typically configured to retain and/or transport fluids within these items. For purposes of this application, these different components are referred to as a pressure system 5 and comprise one or more of the above components and their equivalents and, optionally, other components. A non-limiting example of a pressure system includes a pipeline for transporting natural gas or other hydrocarbons or other fluids. Another non-limiting example is a natural gas or oil well, CO2 well, water well, disposal well and the like, whether being actively drilled or already producing, that typically includes one or more of the following components: a Christmas tree or well head; production tubing; casing; drill pipe; blowout preventers; and other components in the fluid system necessary or appropriate for use in an oil well drilling or production system, as well as the sub-components of each of those items that optionally can be hydraulically isolated and individually tested, and, in some instances, can include the open hole (i.e., uncased) wellbore and the surrounding rock or geological formation. Yet another non-limiting example includes hydraulic and fuel lines of various types for transporting fluids for use in mechanical devices. Yet another non-limiting example includes storage containers for retaining fluids therein. Other pressure systems for transporting or retaining fluids fall within the scope of the disclosure.

The fluids retained or transported within embodiments of the pressure systems 5 typically include one or more gases, liquids, or combinations thereof, including any solid components entrained within the fluid. As one non-limiting example, a typical fluid comprises one or more of methane, natural gas, carbon dioxide, hydrogen sulfide, natural gas liquids, and the like. Another non-limiting example is crude oil, which typically includes methane, propane, octane, and longer-chained hydrocarbons, including heavy oil/asphaltenes. In example of an exploration oil or gas well, the fluids typically include drilling fluids, lost circulation materials, various solids, drilled formation solids, and formation fluids and gases. Yet another non-limiting example is hydraulic fluid within a hydraulic line. Other examples of such fluids include test fluids specifically chosen for the test, including, but not limited to, viscosified water. Other fluids, whether liquid or gas, fall within the scope of the disclosure.

A fluid pumping unit 10 is an optional component of the leak detection system, non-limiting examples of which include cementing units, pumps of various types (e.g., centrifugal, duplex, triplex, positive displacement, eductors) powered by any suitable source of power such (e.g., hydraulic, electric, mechanical). The fluid pumping unit 10 is coupled to the pressure system 5. The fluid pumping unit 10 is configured to supply a selected volume of a test fluid from a source or reservoir of fluid to the pressure system 5. The test fluid, as noted, optionally is selected specifically for the test, such as viscosified water, or a fluid of the type already present in the pressure system 5, or other combinations thereof. The selected volume of test fluid depends, in part, on the size or total volume of the pressure system 5, and can be from small amounts, such as microliters for laboratory equipment, to large amounts, such as barrels (i.e., 42 gallons per barrel) and more, for large pressure systems, as might be expected with pipelines and oil and gas wells. Adding the test fluid to the pressure system 5 raises the pressure at which the fluid within the pressure system 5 is confirmed, such that a test pressure (i.e., the pressure within the pressure system after the test fluid is added to the pressure system) at time₁ is greater than the initial pressure of the fluid in the pressure system 5 at time₀.

Optionally, a flow meter 30, such as a venturi flow meter, pressure flow meter, stroke counter (calibrated to the volume/stroke of a given positive displacement pump), impeller flow meters, and the like and as appropriate, are coupled to the fluid pumping unit 10 to sense the amount of fluid being added to the pressure system 5. The flow meter 30 optionally displays a signal reflective of the flow of the fluid, such as a flow rate, via gauges and/or digital displays. The flow meter 30 optionally transmits a signal reflective of the flow rate to a general purpose computer 15, typically via sensor cables. While FIG. 1 shows the flow meter transmitting a signal via sensor cables, it is contemplated that the flow meter 30 can be configured to transmit the signal wirelessly and even to be connected to the Internet for transmission to a remote general purpose computer 15 configured to receive wireless and/or Internet signals.

The leak detection system 1 also includes at least one pressure sensor 20 coupled to the pressure system 5. The pressure sensor 20 is configured to sense an initial pressure of the fluid within the pressure system 5 at an initial time₀ as well as at subsequent times over an interval ‘n’ of time out to time_((n+1)). The pressure sensor 20 optionally displays a signal reflective of the pressure of the fluid within the pressure system 5, via gauges and/or digital displays. The pressure sensor 20 transmits a signal reflective of the pressure to a general purpose computer 15, typically via sensor cables, although it is contemplated that the pressure sensor 20 can be configured to transmit the signal wirelessly. Of course the signals can be sent through a hard wired system, a wireless system, or by other suitable means such as through the Internet to the general purpose computer 15 if it is so configured. The pressure sensor 20 is typically selected for the particular operating conditions, such as a pressure and temperature range that is expected for the fluid within the pressure system 5. For example, a pressure sensor 20 selected for use in a pressure system that is part of an oil well, such as a blowout preventer, would be capable of sensing pressure in a range from 0 to 15,000 pounds per square inch and sensing a temperature in the range of −40° F. to +250° F. A non-limiting example of such a pressure sensor 20 include the Models 509, 709, and 809 Pressure Transducers available from Viatran, a Dynisco Company, of Grand Island, N.Y. Other pressure sensors 20 suitable for the pressure and temperature conditions expected to be encountered within the pressure system 5 also fall within the scope of this disclosure.

Embodiments of the leak detection system also include a general purpose computer 15. A general purpose computer 15 can include laptop computers, desktop computers, netbook and tablet computers, personal digital assistants, calculators (programmable and otherwise), and other similar devices and can be located at the testing site or remote from the site. The general purpose computer 15 is configured to accept and store an operating program configured to receive data reflective of pressure and temperature and to manipulate and present that data as a function of time on a computer readable medium, such as a hard drive, flash memory, data tapes, jump drives, remote storage, such as cloud computing with a data server or servers, and the like and for further delivery to the user in a suitable visual/readable format. Optionally, the general purpose computer 15 is configured to receive and transmit data wirelessly or over an Internet connection 27 that is, in turn, connected to another graphical output 28 and/or general purpose computer described in further detail below. Other embodiments of the invention include a specific purpose computer configured to process the pressure and temperature signals from the sensor 20, rather than a general purpose computer 15. The specific purpose computer will have an operational program recorded onto a specific instruction computer chip, such as a programmable read only memory, externally programmable read only memory, externally erasable programmable read only memory, and/or hard-wired into a specific instruction computer chip.

Embodiments of the operating program as will be described in further detail below are configured to calculate a leak detection value, which is a function of a variance of the first pressure at time₀ and the test pressure at time₁; the test pressure at time₁ and the test pressure at time₂; and so on for given one and/or more intervals of time ‘n’ to a test pressure at the time_(n) and the test pressure at the time_((n+1)). A benefit of this previously unknown method is its relative simplicity and accuracy.

Embodiments of the leak detection system 1 also include a graphical output 25 coupled to the general purpose computer 15. The graphical output 25 is any suitable device configured to display to the user the temperature and pressure data, as well as the leak detection value as a function of time, such as a chart or graph. Non-limiting examples of a suitable visual include scatterplots, line graphs, and circular chart recorders that emulate analog circular chart recorders. Examples of the graphical output include monitors, printouts generated by a printer, web pages that have had the leak detection value(s) transmitted to them via a server or other Internet connection coupled to the general purpose computer 15, or any other kind or type of dedicated display and/or dumb terminals.

As mentioned above, the test pressure exhibits a change in pressure with time as an effect of a temperature of the fluid (both the test fluid and the first fluid) changes with time. In other words, the test pressure changes over a time interval time₀ to a time_((n+1)), regardless of whether a leak or leaks are present within the pressure system, and often changes at an exponential rate. This effect is particularly noticeable with synthetic fluids composed of long chain hydrocarbon molecules that are compressible to a modest degree under pressure. The net effect is that it can be difficult to determine quickly whether a decrease in pressure is caused by a leak or caused merely by the decrease in pressure as the drilling fluid cools and the thermal compression effect lessens. As a result, and as will be illustrated, it is a typical practice to hold the pressure system at an elevated pressure for extended periods of time until a steady state pressure has been reached. In other words, the temperature and, hence, the pressure of the fluid within the drilling system has reached a relatively constant steady state. In large pressure systems, such as pipelines and oil or gas wells, it might take more than an hour for the pressure system to reach a steady state pressure such that federal regulations for testing such systems are satisfied. It should be noted that it is presently understood that existing federal regulations do not require the tests to occur for such extended period, only that the uncertainty caused by the temperature and compressibility effects cause operators to extend the period of the test to ensure a valid reading the satisfies federal regulations. As a result, it has been observed that significant time is wasted that might otherwise be avoided if a test were available that could quickly evaluate the pressure system and account for the temperature and compressibility effects without need for elaborate models, complex algorithms, detailed and strict test plans, and the like.

An operating program for the general purpose computer 15 (or as hardwired on a silicon chip in a specific computer), utilizes an equation as follows:

${{Leak}\mspace{14mu} {Detection}\mspace{14mu} {Value}} = {\left( {1 - \frac{{Pressure}_{{time}\; 0}}{{Pressure}_{{time}\; 1}}} \right) \times 100}$

It will be understood that multiplying the value by 100 creates a value greater than one, rather than a decimal value less than one, and, therefore, is optional depending on a user's preference. From the above, it can be seen that the leak detection value is a function of the variance of a pressure of a fluid in the pressure system plus the additional, selected volume of the test fluid added to the pressure system at first time₀ and the pressure at a second time. The general purpose computer reads these values as stored in the computer readable medium, which were previously sent by the pressure sensor. Of course, it will be understood that the operating program can read the data and calculate the leak detection value nearly simultaneously with the measurement of the pressure by the pressure sensor or, in other words, in real-time. Once a single leak detection value is calculated, it is stored in the computer readable medium for future use and recall, either as displayed on the graphical output or to be used in additional calculations. The leak detection value is then calculated for subsequent time intervals and test pressures, such as at time₂ and at time₃ and through the test pressure at the time″ and at time_((n+1)), the test pressures at each of those times typically exhibiting a pressure lower than that in the immediately preceding periods and exhibiting an exponential rate of decease (within the limits of error and noise in the measurement of the test pressure by the pressure sensor).

The time interval at which the test pressure is sensed or measured typically occurs over a relatively short period of time, such as every 3 seconds, 15 seconds, 30 seconds, 60 seconds and the like. Of course, other intervals of time may be selected and fall within the scope of the disclosure, including intervals less than a second and up to about or around 30 minutes. Shorter periods typically work better for test pressures that decrease exponentially, particularly if there is a sharp temperature gradient between the fluid within the pressure system and the temperature of the ambient environment surrounding the pressure system It is contemplated that the test pressure data acquired and stored in the computer readable medium optionally undergoes some form of data smoothing or normalizing processes to eliminate spikes or data transients. For example, one may use procedures to perform a moving 3-point average, curve fitting, and other such data smoothing techniques, prior to using it to calculate a leak detection value. This allows for a smoother and, potentially, more readable and accurate representation of the leak detection value with less noise from interference and spurious signals.

Embodiments of the method include providing the components described above, namely, a pressure system 5, a fluid pumping unit 10, a general purpose computer 15, at least one pressure sensor 20, and a graphical output 25, as described above, and, optionally, an Internet or wireless connection 27 connected to another graphical output 28, and a flow meter 30 coupled to the fluid pumping unit 10.

To conduct a leak detection test and calculate the leak detection value, reference is made to the flow charts 700 and 800 in FIGS. 7 and 8. The fluid pumping unit 10 is coupled to the pressure system 5 so that the fluid pumping unit 10 can pump or introduce a selected volume of test fluid into the pressure system 5, as represented at box 705 in FIG. 7, such that fluid within the pressure system 5 is at test pressure, or Ptest, that is at or above a minimum pressure threshold, or Pthreshold. The pressure system should maintain P test without leaking It is understood that the pressure system 5 may already have a volume of fluid at an initial pressure below a test pressure within the pressure system 5 and, therefore, the pressure system 5 requires only an additional, small amount of test fluid to be added. Alternatively, the fluid pumping unit 10 is capable of filling the pressure system 5 in its entirety to its test pressure.

Optionally, as the fluid pumping unit 10 is pumping the test fluid into the pressure system, the flow meter 30 senses the flow rate and/or determines the volume of the test fluid pumped into the pressure system 5 and transmits a signal reflective of those values to the general purpose computer 15 for recording and storage on the computer readable medium, typically with an associated time stamp or other data. Optionally, if the flow rate is sensed or detected and transmitted to the general purpose computer 15, the general purpose computer 15 can be configured to calculate the total volume pumped. Other methods to determine flow rate and/or volume include the use of simple analog or digital stroke counters connected to the fluid pumping unit 10, from which the flow rate and the volume of test fluid pumped can be calculated in the general purpose computer. The flow rate and the total volume of the test fluid can also be displayed on the graphical output 25, along with other optional data.

The pressure sensor 20 can sense the pressure of the fluid within the pressure system 5 and transmit a signal reflective of the pressure to the general purpose computer 15 before, during, and after the fluid pumping unit 10 pumps the test fluid into the pressure system 5, as represented at boxes 710, 715, and 720. The operating program can be configured to automatically and/or continuously record on the computer readable medium the pressure data (and other data as discussed above) once a certain threshold value is reached, such as a minimum pressure, flow rate, volume pumped, and the like, or continuously. Alternatively, it is contemplated that a user manually starts the program and/or instructs it to begin recording the data upon entering a command to do so. As previously noted the pressure data (and other data) may be averaged, normalized and/or smoothed prior to displaying and/or using it to calculate the leak detection value. The data optionally is displayed on the graphical output 25 or transmitted wirelessly and/or through an Internet connection 27 to another graphical output 28.

The operating program calculates the leak detection value in accordance with the formula above for a selected time interval, as noted at box 725. In one embodiment, the computer can be configured to continuously calculate and/or recalculate a leak detection value that is the variance of the test pressure at time 0 and the test pressure at time 1 subtracted from unity and multiplied by 100 to generate a leak detection signal reflective of the leak detection value. In another embodiment, the leak detection value is a function of a variance of the test pressure at time] and the test pressure at time₂; the test pressure at time₂ and the test pressure at time₃; through the test pressure at the time and the test pressure at said time_((n+1)). The leak detection values may also be smoothed, such as by averaging (e.g., 3-point moving average), curve fitting, normalizing techniques, continuous averaging techniques and/or otherwise smoothed. The leak detection values optionally are recorded to the computer readable medium, typically with an associated time stamp. In addition, the leak detection values are optionally displayed as raw data and/or as a graphical plot or chart on the graphical output 25.

Step or box 730 requests a decision for the question of whether this is the initial leak detection test conducted on the pressure system 5. If it is the initial leak detection test, measurements of the test pressure typically are taken for a selected period of time, such as five, ten, 15 minutes, or longer, depending on the pressure system 5, to ensure a valid test and to characterize the pressure decrease and the leak detection value as a function of time. In other words, the selected volume of test fluid is held within the pressure system 5 until the test is concluded and the additional fluid and/or pressure introduced into the pressure system to conduct the test is bled off or released.

If the decision at box 730 of FIG. 7 is “No”, and this is not the initial leak detection test, then the decision as to the significance of the calculated leak detection value is determined using the flow chart 800 in FIG. 8 and, more specifically, box 805, which is discussed in detail below.

If the decision at box 730 is “Yes”, i.e., this is the initial leak detection test, then the process proceeds to box 740. In this step, the general purpose computer 15 is configured to determine whether the leak detection value calculated in box 725 meets a certain leak threshold or minimum that is preset by the user. For example, it might be that a leak detection value of less than ±0.1 or ±0.2 (the leak detection value is a unitless indicator) indicates a valid test. That is, any decrease in the pressure of the pressure system 5 as measured by the pressure sensor 20 during which the test fluid is being pumped or held within the pressure system 5 is typically the result of the temperature and compressibility effects of the fluid rather than an indication of a leak within the pressure system 5. To avoid dealing with the confusion of “negative numbers: the leak detection value can be manipulated so that it will always be a positive number. Thus the leak detection value can be multiplied by a coefficient or other factor, to always output a positive value (such as by multiplying any negative results by −1), for example. Other manipulation of the leak detection value falls within the scope of disclosure. Further, other threshold minimums for the leak detection value may be selected depending upon the type of pressure system 5 being tested. For example, laboratory equipment that uses very small volumes of fluid might have a lower threshold value, such as 0.05 because the effect of the temperature gradient on such small volumes is proportionally greater. This threshold value can be observed on a plot or chart with a display of the calculated leak detection values as output on the graphical display, or it may be a simple pass/fail type display, or other similar type of output. Preferably the values are displayed graphically.

If the leak detection value meets the minimum leak threshold value, i.e., box 740 is answered “Yes”, box 745 indicates that operating program records this as a good test and the leak detection values are recorded as a benchmark by which future leak detection tests of the same or similar components are evaluated.

In the next step 765, the method operates to determine whether there are additional leak detection tests to be conducted on the pressure system 5, such as when testing individual components of a pressure system 5 that are capable of being hydraulically isolated from other components of the pressure system 5. An example of such an instance is the testing of a blowout preventer on an oil well, as blowout preventers typically include one or more annular rams and one or more pipe, blind, and/or shear rams, each of which can be hydraulically isolated and tested separately from the other components of the blowout preventer.

If no additional tests are contemplated, a leak detection test report, such as a summary of the data, the outcome of the test or tests, and associated graphs and/or plots can be prepared for storage on the computer readable medium and/or output via the graphical display, whether onscreen or as a hard copy printed out, and/or transmitted either wirelessly or via the Internet to another graphical display. This step is indicated at box 775.

If additional leak detection tests are contemplated, indicated as box 770, preparations for the next test are made and the process begins anew, as indicated at box 705.

Turning back to box 740, if the leak detection value does not meet the minimum threshold value to indicate a passed test, i.e., the leak detection value indicates that a leak is present or some other factor is causing the pressure system 5 to lose pressure more rapidly than can be accounted through temperature and compressibility effects, then the decision turns to box 750 that notes to display “Failed Test.” This failure can be observed on a plot or chart with a display of the calculated leak detection values as output on the graphical display, or it may be a simple pass/fail type display, or other output that provides an indication perceivable or detectable by the user. Typically, the failure is also recorded in the computer readable medium so that the result optionally can be recalled and compared to leak tests that occurred previously, perhaps weeks and months ago or even longer. Of course storage in the memory allows for comparison with tests that occur in the future.

Box or step 755 indicates that the source of the leak or the cause of the loss of pressure is trouble shot and/or repaired, with the leak detection test repeated at step 760, as indicated by the return to the beginning of the method at box 705.

Turning back to the decision at step 730, i.e., whether this is the initial leak detection test, if the answer is “No” the method then proceeds to decision or diamond 805 as indicated on the flow chart 800 in FIG. 8. As this particular test is a subsequent test, i.e., not the initial leak detection test, decision step 805 compares the leak detection value with or against the initial leak detection values stored as a benchmark in step 745.

When the leak detection value is compared against the benchmark and produces a result where the leak detection value is less than or equal to the benchmark, the general purpose computer produces a result that is displayed or communicated to the user indicating that the test was good at step 810. It should be noted that typically subsequent tests will be compared against the validated benchmark, although it is not required to be so compared. In addition, comparing subsequent tests to a validated benchmark typically results in time savings, as the additional test fluid and/or elevated test pressure is then typically held for a shorter period of time, such as 5 minutes, as compared to the time that the test fluid and/or elevated test pressure is held during the initial or benchmark test. If the calculated leak detection value is less than or equal to the benchmark and/or within a certain amount of the benchmark, the test is declared good at box 820, which then points to decision box or step 765 in which it must be determined if more tests are to be performed as previously described. If the leak detection value at decision step 810 falls outside the range of acceptable values as compared to the validated benchmark, then the method returns to step 750 as previously described.

Other methods of comparing subsequent leak detection values to the initial or validated benchmark leak detection values include comparing an average leak detection value across the entire time interval for a given series of multiple tests, and subtracting that average from the average value of a specific test over the same interval. Another option is to subtract the leak detection values of the benchmark test at a specific time interval from the subsequently calculated leak detection value of another test at the same time interval. Other methods of manipulating and displaying the leak detection values fall within the scope of the disclosure.

Instead of comparing the leak detection values to a validated benchmark as described in step 810, the leak detection values optionally can be compared to the minimum threshold, as noted at decision step or box 815, which is similar to box 740. If the leak detection value meets the minimum threshold, a good test and the flow chart also directs towards step 820. If the leak detection values do not meet the threshold, the method returns to step 750 as previously discussed.

Two examples of the system and method of leak detection will be described below and with reference to FIGS. 2-6.

Both examples refer to data acquired at a well site, in particular, a deepwater exploration well in which the blowout preventer and, more specifically, various subcomponents of the blowout preventer that can be hydraulically isolated from the other components, are tested for leaks and pressure integrity to satisfy federal regulations. It should be noted that while the two examples relate to blowout preventer and oil and gas drilling, the scope of the disclosure extends to other pressure systems as described above.

FIG. 2 is a representation of an embodiment of the leak detection system and includes a pressure system 5A that includes, in this example, flow line 4 (which may be one or more flow lines) that are configured to couple a fluid pumping unit 10A, typically a cementing unit when on a drilling rig, to one or more annular rams 6 and one or more shear rams and/or pipe rams 7. Additionally, while the examples do not extend to testing the following components, FIG. 2 also illustrates the casing 8, open well bore 9, and the formation or geological structure/rock 11 that surrounds the open well bore 9. As previously noted, the method and system described herein extends to these elements for leak detection and pressure integrity testing.

Also illustrated in FIG. 2 is a flow meter or flow sensor 30A coupled to a general purpose computer 15A that includes an operating program and computer readable medium, as previously described. Also illustrated are two pressure sensors 20A and 20B coupled to the pressure system SA, one at the surface and one at the blowout preventer. Other pressure sensors may be located at the same or different locations of the pressure system 5A and fall within the scope of the disclosure. The pressure sensors 20A and 20B shown are coupled to the general purpose computer 15A as described above. A graphical output 25A comparable to that described above, is coupled to the general purpose computer 15A.

EXAMPLE 1

Pressure, flow rate, and the volume of test fluid pumped are graphed on the chart 300 in FIG. 3, which illustrates a series of high pressure tests to several subcomponents of the blowout preventer illustrated in FIG. 2. It is likely that some of the subcomponents are the same type so that the volume pumped for the test of such subcomponents will be effectively the same, as will be explained below. For example, a typical blowout preventer has several pipe rams, each of which must be hydraulically isolated and tested separately in accordance with federal regulations. The pipe rams are typically identical from a mechanical standpoint, so the volume of fluid pumped will be the same leading toe similar test results if there are no leaks or defects. Other components of the blowout preventer that optionally can be tested with the methods and systems described herein include, but are not limited to, the manifold, choke lines and kill lines.

The abscissa (e.g., horizontal axis), is the time axis 305, which shows or plots time on an hourly basis, with the gradations marking 15 minute increments. The left vertical or ordinate axis is a pressure axis 310 showing the pressure of the pressure system 5 (FIG. 1) as measured by the pressure sensor 20, and includes increments or gradations for every 1,000 pounds per square inch (psi) with minor gradations marking 200 psi increments. The right ordinate is also known as the flow rate axis 320 and presents the rate at which the test fluid is pumped by the fluid pumping unit 10 (FIG. 1) as measured by the flow sensor 30 and/or as calculated by the operating program as noted above. The flow rate axis 320 has major gradations for every 0.5 barrels per minute (bbl/min), or 21 gallons per minute, with minor gradations for every 0.1 bbl/min. The right ordinate axis is also called the test fluid volume axis 315 and shows the total test fluid volume pumped by the fluid pumping unit 10 as measured by the flow sensor 30 and/or as calculated by the operating program as noted above. The test fluid volume axis 315 has gradations for every barrel and minor gradations for every 0.2 barrels of total volume of test fluid pumped.

Five separate leak detection tests, 331, 332, 333, 334, and 335 are plotted on the chart 300 typically on the graphical display 25 (FIG. 1). Test 331 output includes the ordinate pressure test axis 310 to present the measured/sensed pressure 341 against the time axis 305. Also, the measured/calculated test fluid volume 351 is plotted over time using the time axis 305 against the test fluid volume axis 315. The test fluid flow rate 361 read against the flow rate axis 320, and the ti . . . I l1e (time₀ to time_((n+1))) over which the leak detection value for test 331 is calculated as indicated by span 371. In other words, the span 371 indicates the time interval time₀ to timeD+1 over which the leak detection value is detected, with the initial time₀ occurring at the start of the span 371, the span 371 being divided into the various intervals to time_((n+1)). This process, as discussed above and illustrated in FIGS. 7 and 8, is repeated for each test.

Test 332 includes the measured/sensed pressure 342 read against the pressure axis 310 versus the time axis 305. Similarly, the measured/calculated test fluid volume 352 is plotted using the test fluid volume axis 315 and the time axis 305. The test fluid flow rate 362 is depicted using the flow rate axis 320 versus the time axis 305. The time (time₀ to time_((n+1))) over which the leak detection value is calculated for test 332 as indicated by span 372.

Test 333 shows the measured/sensed pressure 343 using the pressure axis 310 and the time axis 305. The measured/calculated test fluid volume 353 is plotted using the test fluid volume axis 315 against the time axis 305. The test fluid flow rate 363 is plotted using the flow rate axis 320 and the time axis 305. Of course the time (time₀ to time_((n+1))) over which the leak detection value is calculated for test 333 is indicated by span 373.

Test 334 similarly includes the measured/sensed pressure 344 plotting the read against the pressure axis 310 against the time axis 305. The measured/calculated test fluid volume 354 is plotted using the volume axis 320 and the time axis 305 The test fluid flow rate 364 is shown plotted using the flow rate axis 320 and the time axis 305. The time (time₀ to time_((n+1))) over which the leak detection value is calculated for test 334 is indicated by span 374.

Test 335 includes the measured/sensed pressure 345 read using the pressure axis 310 and the time axis 30. The measured/calculated test fluid volume 355 is plotted using the test fluid volume axis 315 and the time axis 305. The test fluid flow rate 365 is plotted using the flow rate axis 320 and the time axis 305. Of course the time (time₀ to time_((n+1))) over which the leak detection value is calculated for test 335 is indicated by span 375.

It will be noted that the total test fluid volume pumped 351,352,353,354, and 355 for each test is effectively the same. Thus, the data suggests that the tests 331, 332, 333, 334, and 335 are for mechanically similar components, such as for a series of pipe rams in the blowout preventer and as discussed previously.

Each of the measured pressure curves 341, 342, 343, 344, and 345 indicate a general exponential decay in the pressure as time passes, as discussed previously. The difficulty is to distinguish the normal and unharmful decrease in pressure from a loss or decrease in pressure that is reflective of a leak. Thus, the values of the pressure, as visually represented in curves 341, 342, 343, 344, and 345, are used as data or input values to calculate leak detection values as described above.

The graph or chart 400 of leak detection values 431, 432, 433, 434, and 435, that correspond with the leak detection tests 331, 332, 333, 334, and 335 over the time intervals 371, 372, 373, 374, and 375 are plotted in chart 400 in FIG. 4. The leak detection values are calculated in accordance with the method and the system as described above. The abscissa or horizontal time axis 405 has major gradations for every minute and minor gradations for every 15 seconds. The leak detection value axis 410 is the vertical or ordinate axis and, as previously, noted, is a unitless value with major gradations every 0.1 unit and minor gradations for every 0.02 units.

It is very apparent from chart 400 that leak detection values 431, 434, and 435 corresponding to tests 331, 334, and 335 in FIG. 3 are all around zero, indicating that the decrease in pressure is a result of the expecting thermal effect/decrease in temperature of the test fluid and the compressibility effect, rather than a leak.

On the other hand, leak detection values 432 and 433 have a significantly different character when plotted on chart 400 as compared to the leak detection values 431, 434, and 435. Thus, whether establishing a minimum threshold leak detection value of 0.1 for example, or comparing the leak detection values 432 and 433 against the other leak detection values 431, 434, and 435, which are good and usable as a benchmark, the slopes or graphs associated with leak detection values 432 and 433 indicate clearly that the pressure system tested in 332 and 333 differs dramatically from the others 431,434 and 435. This difference suggests there is failure of the system 5 and that it is leaking. AB it turns out, the pressure system tested at 332 suffered a small, leaking valve early in the test, which was then closed, resulting in a leak detection value 432 that quickly returned to the pattern set by leak detection values 431, 434, and 435. The pressure system tested at 333 having a leak detection value curve of 433 suffered a slow leak in the system and, therefore, failed as a whole.

It should be noted that the conclusions reached about integrity of the system (i.e., leak or no leak) can be made quickly based on the leak detection values 431, 432, 433, 434, and 435. In the examples, the determination can be made in a period of time under 10 minutes. It is believed that reliable data and a relatable determination can be made in as little as 3 minutes; and in some systems, the determination can be made even in a period of less than 1 minute. As can be seen from the pressure data plotted in curves 341, 342, 343, 344, and 345 in FIG. 3, if each test would have been continued for approximately another 5 to 8 minutes until the pressure and test fluid were bled off would be unnecessary. In other words, over a period of five longer tests an additional 25 to 40 minutes of time would be spent testing the pressure systems; and that time would have been unnecessary if the present leak detection systems and methods were used.

Thus, example 1 illustrates that the system and method of leak detection as herein disclosed is fast and reliably indicative of defects.

EXAMPLE 2

Example 2, as illustrated in the charts 500 and 600 in FIGS. 5 and 6, respectively, use data from tests of several different subcomponents of the blowout preventer that is significantly more noisy than that used in Example 2.

In FIG. 5, abscissa or horizontal axis is also called the time axis 505 which shows time with major gradations or intervals every two hours and minor intervals or gradations in 30 minute increments. The ordinate or left vertical axis can be called the pressure axis 510 which reflects the pressure of the pressure system 5 (FIG. 1) as measured by the pressure sensor 20. The pressure axis 510 has major gradations or intervals for every 2,000 pounds per square inch (psi) with minor gradations or intervals marking 500 psi increments. The ordinate or vertical flow rate axis 520 shows the rate at which the test fluid is pumped by the fluid pumping unit 10 as measured by the flow sensor 30 and/or as calculated by the operating program as noted above. The flow rate axis 520 has major gradations or intervals for every 0.5 barrels per minute (bbl/min), or 21 gallons per minute, with minor gradations between the major showing 0.1 bbl/min. The vertical test fluid volume axis 515 indicates the total test fluid volume pumped by the fluid pumping unit 10 as measured by the flow sensor 30 and/or as calculated by the operating program as noted above and has major gradations or intervals for every barrel and minor gradations or intervals for every intervening 0.2 barrels of the total volume of test fluid pumped.

Six separate leak detection tests, 532, 533, 534, 535, 536, and 537 are plotted on the chart 500. Test 532 includes the measured/sensed pressure 542 on the pressure axis 510 read against the time axis 505. The measured/calculated test fluid volume 552 is plotted from axis 515 against the time axis 505. The test fluid flow rate 562 from axis 520 is plotted against the time axis 505. The time (time₀ to time_((n+1))) over which the leak detection value is calculated for test 532 as indicated by time span 572.

Test 533 includes the measured/sensed pressure 543 on the pressure axis 510 read against the time axis 505. The measured/calculated test fluid volume 553 is plotted from axis 515 against time axis 505. The test fluid flow rate 563 from axis 520 is plotted against the time axis 505. The time (time₀ to time_((n+1))) over which the leak detection value is calculated for test 533 is indicated by span 573.

Test 534 includes the measured/sensed pressure 544 on the pressure axis 510 read against the time axis 505. The measured/calculated test fluid volume 554 is plotted from axis 515 against time axis 505. The test fluid flow rate 564 from axis 520 is plotted against the time axis 505. The time (time₀ to time_((n+1))) over which the leak detection value is calculated for test 534 is indicated by span 574.

Test 535 includes the measured/sensed pressure 545 on the pressure axis 510 read against the time axis 505. The measured/calculated test fluid volume 555 is plotted from axis 515 against the time 505. The test fluid flow rate 565 from axis 520 is plotted against the time axis 505. The time (time₀ to time_((n+1))) over which the leak detection value is calculated for test 535 is indicated by span 575.

Test 536 includes the measured/sensed pressure 546 on the pressure axis 510 read against the time axis 505. The measured/calculated test fluid volume 556 is plotted from axis 515 against time axis 505. The test fluid flow rate 566 from axis 520 is plotted against the time axis 505. The time (time₀ to time_((n+1))) over which the leak detection value is calculated for test 536 as indicated by span 576. It should be noted that the data from test 536 appears to be indicate that the test was aborted.

Test 537 includes the measured/sensed pressure 547 on the pressure axis 510 read against the time axis 505. The measured/calculated test fluid volume 557 is plotted from axis 515 against the time axis 505. The test fluid flow rate 567 from axis 520 is plotted against the time axis 505. The time (time₀ to time_((n+1))) over which the leak detection value is calculated for test 537 is indicated by span 577.

It will be noted that the total test fluid volume pumped 552 and 553 in tests 532 and 533 are nearly the same. Thus, the data suggest that the tests 532 and 533 are for mechanically similar components, such as for a series of annular rams in the blowout preventer as discussed previously. Similarly, the total test fluid volume pumped 554, 555, 556, and 557 are nearly the same. Thus, the data suggest that the tests 534, 535, 536, and 537 are also for mechanically similar components, such as, for example, a series of pipe rams in the blowout preventer as discussed previously. Of course, and as previously discussed, the data for these components tested are merely exemplary; and the systems and methods disclosed herein are capable of testing other components of the blowout preventer, as well as different pressure systems as set forth in the hereinbefore.

Each of the measured pressure curves 542, 543, 544, 545, 546, and 547 show a general exponential decay in the pressure as time passes. This reflects, in part, a change in temperature as discussed previously. AB stated, the it is important to differentiate between the normal decrease in pressure from a decrease in pressure relating to a problem such as a potentially harmful leak. Thus, the values of the pressure, as visually represented in curves 542, 543, 544, 545,546, and 547 are used as data input values to calculate leak detection values as described above. Further, it should be noted that in tests 532 and 533, it is believed that additional test fluid was added to the pressure system 5, raising the pressure as the pressure curves 532 and 533 indicate. The flow rate curves 562 and 563 and volume curves 552 and 553 also indicate this. Regardless of the reason for adding the additional fluid, chart 600 of the calculated leak detection values will illustrate that the presently disclosed method and systems quickly and more easily allow the user of the present system to identify good tests (not leaking) from leaking pressure systems.

The chart 600 of the leak detection values 632, 633, 634, 635, 636, and 637 that correspond with the leak detection tests 532, 533, 534, 535, 536, and 537 over the time intervals 572, 573, 574, 575, 576, and 577 are plotted in chart 600 in FIG. 6. The leak detection values are calculated in accordance with the method and using the system as described above. The abscissa or horizontal time axis 605 has major gradations for every minute and minor gradations for every 15 seconds in between the minutes. The leak detection value axis 610 is the ordinate or vertical axis and, as previously, noted, is valueless with major gradations every 0.1 units and minor gradations indicating 0.02 units.

By inspecting the chart 600 it can be seen that notwithstanding the different volumes used in the tests leading to curves 552, 553, 554, 555, 556, and 557 and pressures 542, 543, 544, 545, 546, and 547 for the respective tests, each of the leak detection values 632, 633, 634, 635, 636, and 637 all fall within the range 0.0 to negative 0.08 (−0.08) within the first 30 seconds of the test and hold relatively constant over the next 8.5 minutes. Thus, it can be seen that none of the tests indicate the existence of a leak when compared to the character of the leak detection values 532 and 533 of FIG. 5 that reflect a defect such as a leak. It can also be seen that embodiments of the presently disclosed method and system work accurately despite sometimes poor and/or inconsistent data, such as that created by spurious signals and/or improper procedures and/or with inexperienced fluid pumping unit operators.

It should also be noted that for purposes of the validation, test 532 and leak detection value or curve 632 was selected as a benchmark as typically would be the case when conducting the test in real-time at a well site. The remaining tests show good correlation of the leak detection values.

It should also be noted that the leak detection values 634, 635, and 637 (as previously noted, test 536 appears to have been aborted quickly) of the different subcomponents of the blowout prevent show good correlation with the leak detection values 632 and 633 of the subcomponents leak tested in 532 and 533. Thus, it can be observed that the leak detection values provide consistent response despite the different subcomponent systems being tested.

Further, it is observed that the leak detection values 431, 432, 433, 434, and 435 fell in a range of approximately ±0.02 after 30 seconds for tests 331, 332, 333, 334, and 335 that occurred at pressures 341, 342, 343, 344, and 345 of between approximately 5,000 psi to 5,400 psi.

In comparison, it is observed that the leak detection values 632, 633, 634, 635, and 637 fell in a range of approximately 0 to about 0.08 after 30 seconds for tests 532, 533, 534, 535, and 537 that occurred at pressures 541, 542, 543, 544, 545, 547 of between approximately 10,300 psi to 11,500 psi. It should be noted that at high pressures, the pressure sensors like sensor 20, typically experience higher noise and reduced accuracy. In short, they are less accurate and produce a less stable output. The lack of stability impacts on the leak detection value and likely accounts for a portion of the difference in the values between the two examples. Thus, despite the significant difference in testing pressure, the leak detection values each fall within the range of ±O.I, which can be selected as an optional, general threshold value for the leak detection.

Turning back to FIGS. 5 and 6, it should be noted that the system and method operates so that the determination of whether there is a malfunction such as a leak can be made based on the leak detection values 632, 633, 634, 635, and 637 in under 10 minutes and, in many instances, less than that. However, normal pressure testing shows pressure data plotted in curves 542, 543, 544,545, and 547 in FIG. 5 for tests that continued from a minimum of about IS minutes to approximately 1.5 hours. To test the whole system, the operator would consume following the procedures of the prior art, at least 4.25 hours. In other words, the present leak detection systems and methods disclosed herein yield significant savings in time and in turn in money.

EXAMPLE 3

The use of the embodiments of the methods and systems disclosed herein are not limited to pressure systems that operate at pressures of several thousand pounds per square inch. Indeed, the methods and systems disclosed can be used, as noted, for pressure systems that operate at pressures that are orders of magnitude lower than the previous examples, including, but not limited to, low-pressure tests for the systems disclosed above, such as low pressure fluid lines, laboratory equipment, and the like.

A further advantage of embodiments of the methods and systems disclosed is that they have the capability of measuring and validating pressure tests and detecting leaks on pressure systems that undergo a first pressure test at a first pressure and subsequently undergo a second pressure test at a second pressure. The second pressure optionally is significantly different than the first pressure and, optionally, the second pressure is orders of magnitude higher or lower than the first pressure. A disadvantage of the prior art is that resolution of the data and methods of presenting the data makes the validation of widely divergent test data quite difficult and, in some instances, impossible. For example, an analog circular chart recorder used in prior art methods typically has a scale from 0 to 15,000 psi, with major gradations of 1,000 psi and minor gradations of 250 psi. Such a scale may be appropriate for high pressure tests of several thousand psi, but the resolution is unacceptable with low pressure tests of a few hundred psi.

Turning to Example 3, illustrated in the charts 300 and 1000 in FIGS. 9 and 10. More specifically, FIG. 9 plots the same data from tests of several different subcomponents of the blowout preventer demonstrated in FIG. 3. That is, FIGS. 3 and 9 are the same chart with the same data, but FIG. 3 provides element numbers and a discussion of a high pressure test of the components, whereas FIG. 9 provides element numbers and a discussion of a series of low pressure tests that preceded each of the high pressure tests.

For clarity and to avoid clutter, FIGS. 3 and 9 repeat only a few common elements rather than all of the elements common to each chart. More specifically, the abscissa or horizontal axis is the time axis 305. The time axis has larger units of time on an hourly basis, with the minor gradations for 15 minute increments. The ordinate or left vertical axis is the pressure axis 310 which shows the pressure of the pressure system 5 (FIG. 1) as measured by the pressure sensor 20. The left vertical axis show major gradations for every 1,000 pounds per square inch (psi) with minor gradations between the major gradations marking 200 psi increments. The flow rate axis 320 reflects the rate at which the test fluid is pumped by the fluid pumping unit 10 as measured by the flow sensor 30 and/or as calculated by the operating program as noted above. The flow rate axis 320 has major gradations for every 0.5 barrels per minute (bbl/min), or 21 gallons per minute, with minor gradations in between marking every 0.1 bbl/min. The test fluid volume axis 315 indicates the total test fluid volume pumped by the fluid pumping unit 10 as measured by the flow sensor 30 and/or as calculated by the operating program as noted above and has major gradations or units for every barrel and minor gradations or units for every 0.2 barrels of total volume of test fluid pumped.

FIG. 9 plots five separate low pressure leak detection tests, 931, 932, 933, 934, and 935 are plotted on the chart 300. Each of the low pressure tests 931, 932, 933, 934, and 935 precedes in time the high pressure tests 331, 332, 333, 334, and 335, respectively, that were discussed with respect to Example 1 and FIG. 3.

Returning to FIG. 9, low pressure test 931, 932, 933, 934 and 935 each show the measured/sensed pressure 941, 942, 943, 944 and 945 respectively read against the pressure 305. The measured/calculated test fluid volume 951 is plotted using the volume axis 315 against the time axis 305. The test fluid flow rate 961 is plotted using the axis 320 against or using the time 305. The time (time₀ to time_((n+1))) over which the leak detection value is calculated is indicated by spans 971, 972, 973, 974 and 975, respectively.

It will be noted that the total test fluid volume pumped 951, 952, 953, 954, and 955 for each low pressure test is effectively the same. That is, the data suggests that the low pressure tests 931, 932, 933, 934, and 935 are for mechanically similar components, as discussed above in Example 1.

As discussed in Example 1, each of the measured pressure curves 341, 342, 343, 344, and 345 in FIG. 3 indicate a general exponential decay in the pressure as time passes. Further, and as noted, it is the difficulty in distinguishing the normal and unharmful decrease in pressure from a potentially harmful leak.

In the instance of the low pressure tests, it should be noted that the resolution, particularly of the pressure 941, 942, 943, 94, and 945 against the pressure axis 310 in FIG. 9 is relatively poor compared to the resolution of the pressure curves 341, 342, 343, 344, and 345 in FIG. 3 when viewed on the common scale of pressure axis 310. That is, the resolution of the pressure 941, for example, appears relatively constant at about 250 psi, which is in sharp contrast to the resolution for high pressure curve 341 in FIG. 3 which reflects a change in pressure of nearly 250 psi. The presently disclosed methods and systems can optionally display a pressure axis 310 (as well as other axis date) with a user selected and/or pre-selected range of data and, therefore, provide better resolution for a specific range of data for a given test. Nonetheless, one scale may be adequate for a given data set, but rarely will that same scale provide sufficient resolution for another data set, particularly with analog prior art methods that have fixed data ranges for which the data are plotted.

The same method and systems discussed above in Example 1 and elsewhere can be applied to the low pressure tests. That is, a leak detection value is calculated for each low pressure test just as it is for the high pressure test and, optionally, graphically displayed just as the leak detection values 431, 432, 433, 434, and 435 were displayed in FIG. 4.

A further application and benefit of the disclosed methods and systems accrue in the particular scenario in which a low pressure test precedes a high pressure test. The ability to detect a leak during the low pressure test, something not possible given the resolution and capability of prior art methods, permits a user of the present invention to take remedial action to investigate and/or to stop a leak following a the low pressure test and before preceding to the high pressure test phase. Taking preventive or remedial action at the low pressure test phase reduces risk to equipment that might fail catastrophically under high pressures; reduces risk to personnel that might otherwise be in the area of the equipment or pressure systems during which the pressure systems fail while they undergo a high pressure test; reduces the risk to the environment should the pressure systems otherwise fail while they undergo a high pressure test; and reduces the time to detect the leak because a leak could potentially be discovered at the low pressure stage before undertaking the time and money to conduct a high pressure test.

The one or more present inventions, in various embodiments, includes components, methods, processes, systems and/or apparatus substantially as depicted and described herein, including various embodiments, subcombinations, and subsets thereof. Those of skill in the art will understand how to make and use the present invention after understanding the present disclosure.

While the examples present data from a blowout preventer on a drilling rig, it is understood that embodiments of the presently disclosed system and method of detecting leaks work equally well for pressure systems and fluid systems of other types, as disclosed and discussed above. Thus, the examples provided are non-limiting examples.

The present inventions, in various embodiments, includes providing devices and processes in the absence of items not depicted and/or described herein or in various embodiments hereof, including in the absence of such items as may have been used in previous devices or processes, e.g., for improving performance, achieving ease and/or reducing cost of implementation.

The foregoing discussion of the invention has been presented for purposes of illustration and description. The foregoing is not intended to limit the invention to the form or forms disclosed herein. In the foregoing Detailed Description for example, various features of the invention are grouped together in one or more embodiments for the purpose of streamlining the disclosure. This method of disclosure is not to be interpreted as reflecting an intention that the claimed invention requires more features than are expressly recited in each claim. Rather, as the following claims reflect, inventive aspects lie in less than all features of a single foregoing disclosed embodiment. Thus, the following claims are hereby incorporated into this Detailed Description, with each claim standing on its own as a separate preferred embodiment of the invention.

Moreover, though the description of the invention has included description of one or more embodiments and certain variations and modifications, other variations and modifications are within the scope of the invention, e.g., as may be within the skill and knowledge of those in the art, after understanding the present disclosure. It is intended to obtain rights which include alternative embodiments to the extent permitted, including alternate, interchangeable and/or equivalent structures, functions, ranges or steps to those claimed, whether or not such alternate, interchangeable and/or equivalent structures, functions, ranges or steps are disclosed herein, and without intending to publicly dedicate any patentable subject matter. 

1.-22. (canceled)
 23. A leak detection system comprising: a computing device to execute a leak detection program and store data as a function of time; and a pressure sensor coupled to a pressure system and the computing device, the pressure sensor to: sense a first pressure at time₀ and a test pressure of the pressure system at time and time_((n−1)), the test pressure indicating a pressure value of the pressure system after a selected volume of test fluid is applied to the pressure system; and transmit a signal indicative of the first pressure and the test pressure at each of time and time_((n+1)) to the computing device; wherein the leak detection program calculates a leak detection value; wherein the leak detection value is a function of a variance of the test pressure at time and the test pressure at time_((n+1)).
 24. The leak detection system of claim 23, wherein the first volume is zero.
 25. The leak detection system of claim 23, wherein the test pressure decreases over a time interval time_(n) _(—) to a time_((n+1)).
 26. The leak detection system of claim 25, wherein the test fluid is supplied at a first temperature at the first pressure, and wherein the test fluid decreases in temperature causing the test pressure to decrease.
 27. The leak detection system of claim 23, wherein the test fluid is essentially incompressible.
 28. The leak detection system of claim 23, wherein the leak detection value is determined using either the formula: ${{{Leak}\mspace{14mu} {Detection}\mspace{14mu} {Value}} = \left( {1 - \frac{{Pressure}_{{time}\; 1}}{{Pressure}_{{time}\; 2}}} \right)},$ or the formula: ${{Leak}\mspace{14mu} {Detection}\mspace{14mu} {Value}} = {\left( {1 - \frac{{Pressure}_{{time}\; 1}}{{Pressure}_{{time}\; 2}}} \right) \times 100.}$
 29. A leak detection system for detecting a leak in a fluid system having a volume holding a fluid at a pressure, the leak detection system comprising: a pressure sensor to sense the pressure of the fluid in the volume and to supply signals indicative of the pressure over time, including a time₁ following a time₀; and a computing device coupled to the pressure sensor, the computing device to: receive signals indicative of the pressure in the volume; store data indicative of the pressure at time₀ and the pressure at time₁; and calculate a leak detection value comprising a ratio of the pressure at time₀ and the pressure at time₁; and send the leak detection value to a graphical display to display the leak detection value as a function of time.
 30. The leak detection system of claim 29, wherein the pressure decreases from time₀ to time₁.
 31. The leak detection system of claim 30, wherein the fluid is supplied at a first temperature at the first pressure, and wherein the fluid decreases in temperature causing the pressure of the fluid to decrease.
 32. The leak detection system of claim 30, wherein the fluid is essentially incompressible.
 33. A method of detecting a leak in a pressure system, comprising: sensing, by a pressure sensor, a first pressure of a fluid in a pressure system at a time₀; generating and transmitting, by the pressure sensor, a signal indicative of the first pressure to a computing device coupled to the pressure sensor; sensing, by the pressure sensor, a second pressure of the fluid at a time₁; generating and transmitting, by the pressure sensor, a signal indicative of the second pressure to the computing device; storing, in a memory of the computing device, data indicative of the pressure at time₀ and the pressure at time₁; calculating, by the computing device, a leak detection value comprising a ratio of the pressure at time₀ and the second pressure at time₁ and; sending the leak detection value to a graphical display to display the leak detection value as a function of time.
 34. The method of claim 33, wherein the first pressure at time₀ decreases to the second pressure at time₁.
 35. The method of claim 33 wherein the fluid is supplied at a first temperature at the first pressure, and wherein the fluid decreases in temperature causing the first pressure to decrease.
 36. The method of claim 33 wherein the fluid is compressible.
 37. A leak detection system comprising: a pressure sensor coupled to a pressure system having a volume, the pressure sensor to: sense a first pressure of a test fluid in the volume at a time₀ and to sense a second pressure of the test fluid in the volume at a time₁; and transmit signals indicative of the first and second pressures to a computing device; and a computing device to: store a benchmark indication of the pressure system without leaks; receive volume signals from a pump indicating a total amount of test fluid supplied to the pressure system at time₀ and time₁; receive the signals from the pressure sensor at time₀ and time₁; store the volume signals and the pressure signals as test data; and generate output signals based on the test data as a function of time, the output signals indicative of a leak detection value that indicates the difference of the first pressure and the second pressure.
 38. The leak detection system of claim 37 further comprising a graphical display coupled to the computing device, the graphical display to display one of the volume signals and pressure signals at time₀ and time₁, proximate the benchmark indication, to show the presence of a leak.
 39. The leak detection system of claim 37 further comprising a graphical display coupled to the computing device, the graphical display to display the leak detection value as a function of time.
 40. The leak detection system of claim 37, wherein the test fluid is essentially incompressible.
 41. The leak detection system of claim 37, wherein the computing device: calculates a variance that is the ratio of the first pressure divided by the second pressure; and subtracts the ratio from 1 to create a result that is the leak detection value.
 42. A leak detection system for detecting a leak in a fluid system having a volume holding fluid at a pressure, the leak detection system comprising: a pressure sensor associated with the volume of the fluid system to sense the pressure of fluid in the volume and to supply signals indicative of the pressure over time, including time₀ and time₁; a computing device coupled to the pressure sensor, the computing device to: receive the signals indicative of the pressure in the volume; store data reflective of the pressure at time₀ and the pressure at time₁; and calculate a leak detection value comprising a ratio of the pressure at time₀ and the pressure at time₁ subtracted from unity; and send the leak detection value to a graphical display to display the leak detection value as a function of time.
 43. The leak detection system of claim 42 further comprising a graphical output coupled to the computing device, the graphical output to display the leak detection value as a function of time.
 44. The leak detection system of claim 42, wherein the leak detection value is determined using either the formula: ${{{Leak}\mspace{14mu} {Detection}\mspace{14mu} {Value}} = \left( {1 - \frac{{Pressure}_{{time}\; 1}}{{Pressure}_{{time}\; 2}}} \right)},$ or the formula: ${{Leak}\mspace{14mu} {Detection}\mspace{14mu} {Value}} = {\left( {1 - \frac{{Pressure}_{{time}\; 1}}{{Pressure}_{{time}\; 2}}} \right) \times 100.}$ 